高温钎焊立方氮化硼界面微结构

以Ag-Cu-Ti合金为钎料采用真空钎焊的方法在优化的钎焊温度和时间下，实现了立方氮化硼(CBN)与砂轮基体的牢固连接。运用扫描电镜(SEM)、X射线能谱仪(EDS)及X射线粉末衍射仪(XRD)对连接界面的微观组织以及CBN表面生成物的三维形貌、化学成分、物相结构进行了综合分析。结果表明，钎料中的元素Ti向CBN表面扩散富集，生成了针状TiB2和TiN，在磨粒与钎料界面形成化学冶金结合，这是CBN与Ag-Cu-Ti钎料间有良好浸润性和高结合强度的主要原因。磨削对比试验表明钎焊CBN砂轮比电镀CBN砂轮具有更高的磨粒把持强度。     

钛基钎料真空钎焊立方氮化硼的分析

采用Ti-Zr-Ni-Cu钎料在优化钎焊温度和时间下对CBN磨粒进行了真空钎焊试验,实现了CBN与钢基体的高强度连接.采用SEM对CBN表面化合物三维形貌进行了观察分析,采用EDS分析了CBN表面化合物及钎料与钢基体界面成分变化,采用XRD对焊后的CBN磨粒及其表面的化合物进行了物相分析,最后对CBN试样进行了断口分析.结果表明,CBN表面生成了Ti元素的的针状、块状化合物TiB2和TiN,磨粒与钎料间界面形成化学冶金结合,这正是CBN与Ti-Zr-Ni-Cu有良好润湿性和高强度连接的主要原因.断口形貌的分析表明,CBN与Ti-Zr-Ni-Cu钎料间的断口发生在CBN磨粒内部,说明CBN磨料与Ti-Zr-Ni-Cu合金钎料的结合强度大于CBN磨粒本身的强度.     

活性元素Ti在CBN与钎料结合界面的特征

通过扫描电镜、能谱仪、X射线衍射仪研究了Ag-Cu-Ti钎料中的活性元素Ti在钎料与立方氮化硼（CBN）磨粒高温钎焊结合界面的扩散现象，并运用动力学分析对界面反应层的生长过程及反应激活能进行了探讨。结果表明：钎焊过程中，钎料中的活性元素Ti明显向磨粒侧扩散偏聚并发生化学反应，实现了磨粒与基体材料的牢固结合；钎焊CBN磨粒表面生成的TiB2和TiN化合物形貌接近平衡状态下生长的理想形貌；界面反应层在钎焊温度1153K～1193K，保温时间5min～20min之间依据抛物线生长法则所得扩散激活能值表明其生长过程主要受新生TiN影响。     

稀土La改性Ag-Cu-Ti钎料的显微组织和力学性能

系统研究了钎焊CBN工具用稀土元素La改性Ag-Cu-Ti钎料合金的熔化温度、微观组织、显微硬度及钎料与45钢基体钎焊接头抗剪强度.结果表明,稀土元素La对Ag-Cu-Ti钎料合金的熔点影响很小,但是可以促进钎料的合金化,提高其合金化程度,稀土La加入量不超过0.5%(质量分数)时可以改善Ag-Cu-Ti钎料合金的微观组织,使金属间化合物分布更加均匀,提高Ag-Cu-Ti钎料合金的显微硬度,还可以明显改善钎料与45钢基体的钎焊接头抗剪强度.     

Ag-Cu-Ti钎料钎焊金刚石的界面微观组织分析

在真空炉中采用Ag-Cu-Ti钎料对金刚石磨粒进行了真空钎焊试验,实现了金刚石与钢基体的高强度连接.采用SEM对金刚石与钎料界面、金刚石表面碳化物形貌进行了观察分析,采用EDS分析了金刚石与钎料界面的成分变化,采用Raman对焊后的金刚石结构进行了分析.结果表明,Ag-Cu-Ti钎料中的Ti元素在界面处发生偏析,并在金刚石表面生成尺寸小于1 μm块状TiC,金刚石在焊接过程的高温中没有发生石墨化,最后在界面上形成了金刚石/TiC/钎料/钢基体的梯度结合层.     

立方氮化硼钎焊制备磨料砂轮的工艺及性能研究

利用Ag-Cu-Ti活性钎料在真空炉中钎焊,制备了单层钎焊CBN(立方氮化硼)磨料砂轮。实验结果表明,Ag-Cu-Ti合金钎料对立方氮化硼表现出良好的浸润性,并将立方氮化硼牢牢钎焊住。扫描电镜、X-射线能谱和X-射线衍射对界面微区组织的分析研究表明,钎焊过程中Ag-Cu-Ti合金钎料中的Ti向立方氮化硼磨粒界面富集,并与立方氮化硼磨料表面的N和B元素发生反应生成TiN和TiB2。     

银基钎料钎焊金刚石的界面结构及TiC生长机制

在合适的工艺下,采用Ag-Cu-Ti钎料实现了金刚石与钢基体的高强度连接,并剖析了Ag-Cu-Ti钎料与金刚石的界面微区结构.通过对界面处的成分分布和深腐蚀后碳化物TiC形貌的观察,分析了Ti的作用机理、新生化合物TiC的形貌及生长规律.结果表明:在一定的条件下,Ti元素与组成金刚石的碳元素发生反应形成TiC层;碳化物层使钎料与金刚石之间产生冶金结合,并在其界面上形成了金刚石/TiC/钎料/钢基体的梯度结合层.     

超高频感应连续钎焊立方氮化硼磨粒的界面反应机理

采用超高频感应连续钎焊工艺,在不同扫描速度条件下实现了立方氮化硼(CBN)磨粒、Ag-Tu-Ti合金以及基体三者之间的钎焊连接。采用扫描电子显微镜(SEM)和X射线能谱仪(EDX)观察钎焊后的CBN磨粒界面新生化合物形貌。结果表明:随着扫描速度的变化,在CBN磨粒表面生成颗粒状TiN化合物以及针状和六棱柱状的TiB2化合物。其中,TiN尺寸为100 nm左右,而TiB2尺寸小于200 nm。在超高频感应连续钎焊CBN磨粒表面首先生成颗粒状TiN层,然后在TiN层外围形成柱状TiB2层,最终形成CBN/TiN/TiB2/钎料结构。当扫描速度为0.5 mm/s时,可以获得较好的界面新生化合物层结构。     

采用复合钎料钎焊Si3N4陶瓷

采用TiN／Ag—Cu—Ti复合钎料连接Si3N4陶瓷材料，采用扫描电镜观察了接头组织。TiN颗粒与Ag—cu组织结合紧密，并未与钎料基体进行反应，在钎缝中分布比较均匀，形成了局部金属基复合材料组织。由于颗粒与液态钎料之间能够形成较强的毛细作用，提高了活性元素Ti扩散的能力，Ti元素能够充分扩散到钎料与母材的界面上进行反应，生成一层致密的反应层。接头抗剪强度表明，在一定范围内，采用复合钎料可以明显提高接头强度。     

铜基钎料焊接金刚石的界面结构与强度

选用Cu-Sn-Ti活性钎料在钢基体上焊接金刚石磨粒,研究钎料合金与金刚石焊接界面的组织形貌与物相组成,分析不同钎焊温度对焊接界面结构及结合强度的影响.结果表明,钎料合金元素与金刚石在钎焊过程中发生化学反应,生成化合物TiC,CuTi和CuSn等,实现了铜基钎料、金刚石颗粒与钢基体之间的化学冶金结合.当钎焊温度为880～930℃时,均可获得连接良好的钎焊接头;钎焊温度900℃时,焊接界面形成的化合物层均匀连续且界面致密,此时在相同磨削条件下,钎焊金刚石试件的磨损失重很小,达到了焊接界面的强力结合.     

新型的治疗阿尔茨海默氏症药物(1-二甲基磷酰基-2,2,2-三氯)-乙基-1-醇烟酸醋对体外神经细胞的作用

目的: 观察本实验室合成的一种治疗阿尔茨海默氏症(AD)的药物(1-二甲基磷酰基-2, 2, 2 -三氯)-乙基^-1-醇烟酸醋(NMF),对体外培养的皮层神经细胞活性的影响以及对海人藻酸(KA)所致的神经损伤的保护作用。方法: 采用体外培养皮层神经元的方法,解剖分离 15 d胚胎小鼠皮层神经细胞, 接种于 96孔板,48 h 后加药并培养 72 h,以 MIT 法 观察 NMF 对小鼠皮层神经细胞活性的影响;同时将接种于 24 孔板的细胞预先给予 NMF,d 3 时加或不加KA处理后,以台盼蓝染色鉴别并计数死、活细胞,可得出细胞的存活率。结果: NMF 明显促进胎鼠皮层神经元活性,其中 NMF1、0. 1、10nmol·L^-1促进神经元活性增殖率分别高达 34.7%、37.4%、36. 7%, NMF 明显促进正常胎鼠皮层神经元存活卒,与对照组比较,10nmol·L^-1 NMF 对皮层神经元的存活率分别提高 39.3%、73.5%。 NMF能显著 对抗 KA 所致的神经元损伤,与 KA 损伤组相比, NMF0.1、10、10nmol·L^-1对损伤皮层神经元的保护率分别为 77.30%、80.10%、84.15%。结论: NMF 明 显促进胎鼠皮层神经元的洁性、提高正常皮层神经元,的存活卒,并能有效地保护KA所致的神经元损伤,提示 NMF 是一种很有潜力的治疗 AD 的药物。     

Rheology Feature of Simple Metal Melt

The rheology feature of Sb, Bi melt and alloys was studied using coaxial cylinder high-temperature viscometer. The results showed that the curve of torsion-rotational speed for Sb melt presents a linear relation in all measured temperature ranges, whereas for the Bi melt, the curve presents obvious non-Newtonian feature within the low temperature range and at relative high shear stress. The rheology feature of Sb80Bi20 and Sb20Bi80 alloy melts was well correlated with that of Sb and Bi, respectively. It is considered that the rheology behavior of Sb melt plays a crucial role in Sb80Bi20 alloy and that of Bi melt plays a crucial role in Sb20Bi80 alloy.     

Microstructures and Mechanical Properties of a Newly Developed Austenitic Heat Resistant Steel

The effect of heat treatment on the microstructures and mechanical properties of a newly developed austenitic heat resistant steel(named as T8 alloy) for ultra-supercritical applications have been studied. Results show that the main phases in the alloy after solution treatment are γ and primary MX. Subsequent aging treatment causes the precipitation of M_(23)C_6 carbides along the grain boundaries and a small number of nanoscale MX inside the grains. In addition, with increasing the aging temperature and time, the morphology of M_(23)C_6 carbides changes from semi-continuous chain to continuous network.Compared with a commercial HR3C alloy, T8 alloy has comparable tensile strength, but higher stress rupture strength. The dominant cracking mechanism of the alloy during tensile test at room temperature is transgranular, while at high temperature, intergranular cracking becomes the main cracking mode, which may be caused by the precipitation of continuous M_(23)C_6 carbides along the grain boundaries. Typical intergranular cracking is the dominant cracking mode of the alloy at all stress rupture tests.     

Three-Dimensional Growth of Coherent Ferrite in Austenite: A Molecular Dynamics Study

Coherent second phase often exhibits anisotropic morphology with specifi c orientations with respect to both the second and the matrix phases. As a key feature of microstructure, the morphology of the coherent particles is essential for understanding the second-phase strengthening eff ect in various industrial alloys. This letter reports anisotropic growth of coherent ferrite from austenite matrix in pure iron based on molecular dynamics simulation. We found that the ferrite grain tends to grow into an elongated plate-like shape, independent of its initial confi guration. The fi nal shape of the ferrite is closely related to the misfi t between the two phases, with the longest direction and the broad facet of the plate being, respectively, consistent with the best matching direction and the best matching plane calculated via the Burgers vector content(BVC) method. The strain energy calculation in the framework of Eshelby's inclusion theory verifi es that the simulated orientation of the coherent ferrite is energetically favorable. It is anticipated that the BVC method will be applicable in analysis of anisotropic growth and morphology of coherent second phase in other phase transformation systems.     

The 15th Global Foundry Sourcing Conference 2014held in Qingdao China

Organized by Suppliers China Co., Ltd and co-organized by the National Technical Committee 54 on Foundry of Standardization Administration of China, the 15th Global Foundry Sourcing Conference 2014 （hereinafter referred to as FSC 2014） was successfully held on Sep. 23rd in Grand Regency Hotel, Qingdao. More than 500 delegates from home and abroad attended this conference, including over 130 purchasers from 20 countries and 380 domestic and foreign suppliers.     

Secondary Recrystallization Behaviors of Grain-Oriented 6.5 wt% Silicon Steel Sheets Produced by Rolling and Nitriding Processes

By rolling and nitriding processes, 0.23- to 0.3-mm-thick grain-oriented 6.5 wt% silicon steel sheets were produced. The core losses of grain-oriented 6.5 wt% silicon steel at frequencies ranging from 400 Hz to 20 k Hz were lower than that of the grain-oriented 3 wt% silicon steel with the same thickness by 16.6–35.8%. The secondary recrystallization behavior was investigated by scanning electron microscopy, energy-dispersive spectroscopy, and electron backscattered diffraction. The results show that the secondary recrystallization in high-silicon steel sheets develops more completely as the nitrogen content increases after nitriding, secondary recrystallized grain sizes become larger, and the sharpness of Goss texture increases. Because more {110}116 grains in the subsurface and the central layer of the sheets have a lot of 20°–45° high-energy boundaries in addition to Goss grains, {110}116 can be the main component through selective growth during secondary recrystallization when the inhibitor quantity is not enough and inhibitor intensity is weaker. The increases in nitrogen content can increase the inhibitor intensity and hinder abnormal growth of a mount of {110}116 grains and therefore enhance the sharpness of Goss texture.     

Laser Cladded TiCN Coatings on the Surface of Titanium

Laser cladded coatings of TiCN were produced on the surface of titanium. To obtain the optimal techniques, several conditions were tested by varying the laser scanning rate. The choice of shielding gas was also studied. The cladded coatings were then evaluated from the surface mechanics point of view based on their microhardness. The microstructure of some interesting samples was investigated by optical micrographs (OM). The results showed that under the condition of fixed pulse frequency and pulse width, the laser scanning rate and the shielding gas are the main factors influencing the components of coatings. TiCN coatings were decompounded and oxidized during the cladding process in the condition of no shielding gas of N2. X-ray diffraction results indicated that the composite coatings composed of TiCN, TiC, Ti2N, and TiO2 were produced using appropriate techniques. The results indicated that the best condition in terms of the surface microhardness is obtained when the scanning rate is 1.5mm / s, the pulse frequency is 15Hz, the pulse width is 3.0ms, and N2 is chosen as the shielding gas. The microhardness of the composite coatings is about 1331kg · mm - 2, which is about 4 times that of the substrate. The optical micrographs indicated that the cladding zone is made up of TiCN, TiO2, and some interdendritic Ti, but the diffusion zone mainly consists of the dendrites phase, and the cladded depth is about 80?滋m, which is more than 2 times that of the laser nitrided sample. There were no microcracks or air bubbles in the cladded sample, which was cladded using the above optimal techniques.     

Effect of Short-Time Aging on the Pitting Corrosion Behavior of a Novel Lean Duplex Stainless Steel 2002

The effect of short-time aging in the temperature range between 400 and 1000 °C on the pitting corrosion behavior and mechanical property of a novel lean duplex stainless steel(LDSS) 2002 was investigated through the potentiostatic critical pitting temperature(CPT) tests and the Charpy impact tests. Both the pitting corrosion resistance and the toughness of aged specimens degraded due to the precipitation of detrimental secondary phases and the most significant reduction of CPT and impact energy emerged at 650 °C concurrently. The CPT of LDSS 2002 specimen aged at 650 °C decreased by 28 °C, and the impact energy dropped from 69 to 29 J/cm~2 compared with the solution-annealed sample. Transmission electron microscopy characterization showed that the main precipitates in LDSS 2002 were Cr_2N and M_(23)C_6 along the ferrite–austenite grain boundaries.     

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正The Transactions of Nonferrous Metals Society of China,founded in 1991 and sponsored by The Nonferrous Metals Society of China,is published monthly now and mainly contains reports of original research which reflect the new progresses in the field of nonferrous metals science and technology,including mineral processing,extraction metallurgy,metallic materials and heat treatments,metal working,physical metallurgy,powder metallurgy,with the emphasis